JPH0954024A - Sampling device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide such a sampling device as being capable of continuously separating and removing dust from combustion exhaust gas sampled as sample gas and continuously supplying the sample gas to a gas analyzer of high response. SOLUTION: In a sample gas supply passage 3 connecting a gas sampling part 2 and a gas analyzer 4, cyclones 10, 11 to separate dust and smoke from combustion exhaust gas G as sample gas S sampled by the gas sampling part 2 and a pump 21 connected in series thereto to suck the sample gas S are provided. A part of the sample gas S passing through the cyclones 10, 11 is supplied as utility gas U to ejectors 13, 14, provided in the cyclones 10, 11, via the pump 21.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a sampling device for supplying a part of combustion exhaust gas discharged from, for example, a coal-fired boiler or a heavy oil-fired boiler as a sample gas to a gas analyzer.

[0002]

BACKGROUND ART For example, SO ₂ in the combustion exhaust gas discharged from a boiler for burning coal, NO _X, CO _2, C
When continuously analyzing components such as O, it is necessary to sample a part of the combustion exhaust gas and continuously supply this to the gas analyzer as a sample gas. By the way, a large amount of dust and soot (hereinafter referred to as dust) is mixed in the combustion exhaust gas from the boiler, and it is necessary to remove dust during gas sampling. A filter for dedusting was provided in the sample gas supply path connecting the section and the gas analyzer, and dust and the like accumulated in the filter were occasionally removed by blowback.

FIG. 4 shows the above-mentioned conventional sampling device. In this figure, 41 is a flue, through which combustion exhaust gas G flows as shown by an arrow. 42 is this flue 41
The gas sampling unit 42 is inserted in the gas analyzer 42, and the gas sampling unit 42 is connected to the gas analyzer 44 through the sample gas supply path 43. Then, in the sample gas supply passage 43,
A filter device 45 for removing dust, a sluice valve 46 for measurement, and a pump 47 for sampling are provided. Also, 4
Reference numerals 8 and 49 denote blowback air supply paths for supplying blowback instrumentation air A to the inside and outside of the filter body 45a of the filter device 45, respectively.
1 is provided for each. 52 is a sluice valve 46, 50, 5
The control unit controls the pump 1 and the pump 47.

In the sampling device having the above structure,
When performing gas analysis, only the sluice valve 46 is opened and the pump 47 is operated to perform gas sampling, and dust and the like contained in the collected sample gas S are removed by the filter device 45. The desired sample gas S is supplied to the gas analyzer 44. By the way, since a considerable amount of dust or the like is contained in the combustion exhaust gas from the boiler that burns coal, the dust or the like adheres to the filter body 45a, increasing the pressure loss in the filter 45 and adversely affecting the analysis. Is affected.

Therefore, blowback air A is supplied to the inside and outside of the filter body 45a to perform blowback regularly to remove dust and the like adhering thereto. That is, in this blowback, the sluice valve 46 and the pump 47 are stopped to stop the gas sampling, the sluice valves 50 and 51 are opened, and the blowback instrumentation air A is supplied to the filter device 45. The dust or the like adhering to the filter body 45a is blown off toward the flue 41 side.

[0006]

By the way, as described above, since gas sampling must be stopped when performing the blowback, the time required for the blowback (about 10 to 15 minutes) is No analysis can be done. And this blowback is also 1 per day
It is necessary to perform the process once to four times, and the time that cannot be analyzed (missing time) increases. In particular, in the high-speed response gas analyzer 44, since the sampling flow rate is large (for example, 20 liters / minute), it is necessary to perform blowback more frequently than the above cycle, and in this case, gas analysis cannot be substantially performed. A problem arises.

The present invention has been made in consideration of the above matters, and it is possible to continuously separate and remove dusts and the like in combustion exhaust gas collected as a sample gas, and to provide a high-speed gas analyzer. An object of the present invention is to provide a sampling device that can continuously supply a sample gas.

[0008]

In order to achieve the above object, a sampling device of the present invention is provided with a sample gas supply path connecting a gas sampling part and a gas analyzer as a sample gas sampled by the gas sampling part. A cyclone for separating dust and soot contained in the combustion exhaust gas and a pump for sucking the sample gas are connected in series, and a part of the sample gas that has passed through the cyclone is transferred via the pump to the cyclone. It is supplied as a utility gas to the ejector device provided in the.

A filter device and a dehumidifying device may be connected in series between the cyclone and the pump.

Further, a gas branch section is provided at the latter stage of the pump,
A sample gas supply passage connected to one or more gas analyzers may be connected to this gas branching portion, and a utility gas supply passage to the ejector device may be connected.

Further, the cyclone may be inserted and arranged in the flue.

[0012]

In the above sampling device, dust and the like contained in the combustion exhaust gas can be efficiently and continuously removed. A part of the combustion exhaust gas (sample gas) dedusted by the cyclone is supplied as a utility gas to the ejector device installed in the cyclone, so a separate utility gas (generally instrument air is used) is prepared. In addition, the configuration of piping or the like for supplying this to the ejector device is greatly simplified.

Further, since the cyclone contains a part of dust and the like trapped dust and exhaust gas, when the instrumentation air is used as a utility gas, when it is released into the atmosphere, harmful substances contained therein are removed. Need to be removed,
The above sampling device does not have such a problem.

When a filter device and a dehumidifying device are connected in series between the cyclone and the pump, dust and water contained in the combustion exhaust gas collected from the flue can be removed more reliably. be able to.

Further, a gas branch portion is provided at the latter stage of the pump,
When the sample gas introduction path connected to one or more gas analyzers is connected to the gas branch section and the utility gas supply path to the ejector device is connected, the switching measurement can be smoothly performed.

Furthermore, when the cyclone is inserted and arranged in the flue, the cyclone is heated by the heat in the flue, and the heater for preventing the drainage of the water in the sample gas in the cyclone can be constructed with a small capacity.

[0017]

DESCRIPTION OF THE PREFERRED EMBODIMENTS The details of the present invention will be described below with reference to the drawings. FIG. 1 schematically shows a sampling device according to a first embodiment of the present invention. In FIG.
Reference numeral 1 is a flue, through which combustion exhaust gas G flows, as indicated by the arrow. Reference numeral 2 is a probe as a gas sampling portion inserted and arranged in the flue 1.
Is partially collected as the sample gas S. The probe 2 is connected to the gas analyzer 4 via the sample gas supply path 3. The gas analyzer 4 includes a gas analyzer 4a and a CPU 4 for controlling and processing data.
b, a display unit 4c, and the like, a suction pump (not shown) is provided, and SO ₂ , NO _x , CO ₂ , and CO in the sample gas S supplied through the sample gas supply path 3 are provided.
One or more of the above components can be analyzed continuously and with a fast response.

Reference numeral 5 is a gas introduction pipe connected to the probe 2, and the sample gas S collected is maintained at an appropriate temperature during the course of a cyclone 10 (described later) provided in a sample gas pretreatment device 8 described later. A heater 6 and a temperature sensor 7 are provided for this purpose.

Reference numeral 8 is a sample gas pretreatment apparatus, and in this embodiment, the following members are housed in a housing case 9. That is, 10 and 11 are, for example, mini cyclones (centrifugal force dust collectors) that are provided in a downstream side of the gas inlet pipe 5 in a series relationship with each other via the flow path 12, and these cyclones 10 and 11 are sample gases. It is composed of a centrifuge for centrifuging dust and the like from S and a dust collecting chamber below the centrifuge.
The dimensions of each part of the cyclone 10 at the preceding stage are set so that relatively large dust particles having a particle size of 10 μm or more can be removed. In addition, the cyclone 11 in the latter stage
Is set to have a smaller size, for example, to remove dust having a particle size of less than 10 μm.

Numerals 13 and 14 are ejector devices (also referred to as ejector devices) which are continuously provided below the cyclones 10 and 11.
Then, the utility gas U is supplied through the pipe (utility gas supply path) 15 connected to the gas branching unit 24, which will be described later.
A pipe line (exhaust pipe) 16 on the downstream side of 3, 14 is connected to the flue 1.

Reference numeral 17 denotes a filter device provided in a flow path 18 connected to the outlet of the rear cyclone 11.
It captures dust and the like still remaining in the sample gas S that has passed 0 and 11, and the filter body 17a has a thickness of 1 μm.
It is configured to be able to capture dust and the like below. 19
Is a dehumidifying device such as an electronic cooler provided in the subsequent stage of the filter device 17 and removes the drain contained in the sample gas S. Reference numeral 20 is a flow meter provided in the latter stage of the dehumidifying device 19, and 21 is a suction pump. An exhaust fan 22 is provided to face a ventilation window 23 formed in the storage case 9.

Reference numeral 24 denotes a flow passage 25 on the downstream side of the suction pump 21.
At the gas branch part that is connected to the outside of the storage case 9,
For example, a plurality of sample gas pipes 26 for supplying the sample gas S to the gas analyzer 4 distant from the gas branching portion 24 by, for example, about 10 m to 20 m are connected to the utility gas supply passage 15. The gas branching unit 24 divides the sample gas S sucked by the suction pump 21 into the sample gas S to the gas analyzer 4 and the utility gas U to the ejector devices 13 and 14, and the division ratio is, for example, It is 9: 1.

Reference numeral 27 denotes a control unit provided in the storage case 9 via an appropriate partition wall 28, which controls each part in the sampling device 8 based on the outputs of various sensors such as the temperature sensor 7 and the flow meter 20, and the device. It is configured such that the presence or absence of an abnormality in the inside can be discriminated and the operating state can be appropriately displayed.

Next, the operation of the sampling device configured as described above will be described. When performing gas analysis, by operating the suction pump 21, a part of the combustion exhaust gas G flowing through the flue 1 via the probe 2 is introduced into the gas introduction pipe 5 of the sample gas supply passage 3, and the sample gas is supplied. It becomes S. The sample gas S is adjusted to an appropriate temperature by the gas introduction pipe 5 and introduced into the pre-stage cyclone 10. The sample gas S introduced into the pre-stage cyclone 10 is centrifuged to separate and remove dust particles having a particle size of 10 μm or more contained therein, and the separated dust particles and the like are collected in a dust collection chamber. It falls and is stored.

The sample gas S from which dust has been removed to some extent in the preceding cyclone 10 is introduced into the succeeding cyclone 11 through the flow path 12. The sample gas S introduced into the latter-stage cyclone 11 is centrifuged to separate and remove smaller dust particles having a particle size of less than 10 μm, and the separated dust particles are collected in the dust collection chamber. It falls and is stored.

In this way, the cyclones 10 and 11 having different abilities to separate and remove dusts and the like (different range of particle sizes that can be separated and removed) are arranged in series, and the dusts in the sample gas S are Since the separation / removal of etc. is performed in two stages, it is possible to perform a very rational treatment, and it is possible to remove 98% or more of the dust contained in the sample gas S, Almost clean.

The dust and the like still contained in the sample gas S that has passed through the cyclones 10 and 11 is captured by the filter device 17 provided at the rear stage of the rear cyclone 11. Then, as described above, the filter device 17
Since most of the dust and the like in the sample gas S are removed by the pre-stage cyclone 10 and the post-stage cyclone 11 provided in the above stage, the dust and the like adhering to the filter body 17a are extremely small.

The sample gas S that has been dedusted through the cyclones 10 and 11 and the filter device 17 becomes cleaner, and is introduced into the dehumidifying device 19 in that state to remove the drainage such as water and become a dry state. The dried and clean sample gas S reaches the gas branch portion 24 via the suction pump 21. And 90% of the sample gas S is
The gas is supplied to the gas analyzer 4 through the sample gas pipe 26 and used for gas analysis. The remaining 10% of the sample gas S enters the utility gas supply pipe 15.

The sample gas S that has entered the utility gas supply pipe 15 is supplied as utility gas U to ejector devices 13 and 14 provided in the cyclones 10 and 11, respectively. Therefore, cyclone 1
The dust and the like separated and removed by 0 and 11 are continuously discharged by the utility gas U, and the dust and the like are discharged to the flue 1 through the discharge pipe 16.

As described above, according to the sampling device of this embodiment, even if dust or the like is mixed in the combustion exhaust gas G collected from the flue 1, it is continuously treated by the cyclones 10 and 11 and the filter device 17. Can be removed to
It is not necessary to stop the sampling of the sample gas S,
Therefore, gas analysis can be performed continuously. Further, the utility gas U is supplied to the ejector devices 13 and 14.
Since the gas supplied as is a part of the sample gas S cleaned through the cyclones 10 and 11 and the filter device 17, other instrumentation air or the like is prepared as the utility gas U, or is supplied. No external piping is required, and the structure can be rational and simple.

When the filter device 17 and the dehumidifying device 19 are connected in series between the rear cyclone 11 and the suction pump 21, dust or the like contained in the combustion exhaust gas G collected from the flue 1 Water and the like can be removed more reliably.

Further, when the gas branching section 24 is provided in the latter stage of the suction pump 21, the desired sample gas S can be supplied to the plurality of gas analyzers 4, and the switching measurement can be smoothly performed. With gas analyzer 4
The sample gas S can be supplied to the cyclones 10 and the utility gas U can be supplied to the cyclones 10 and 11 with a very simple structure.

Furthermore, the sampling device in the above-mentioned first embodiment is the cyclone 10, 11, the filter device 1.
7, dehumidification device 19, suction pump 21, control unit 27
Etc. are accommodated in one storage case 9 and installed at a point close to the combustion exhaust gas G. The sampling device configured as described above is suitable for, for example, a coal-fired boiler.

FIG. 2 schematically shows a sampling device according to the second embodiment of the present invention. In this embodiment,
The sample gas pretreatment device 8 is divided into two, one storage case 29 is provided near the flue 1 (that is, the probe 2), and another storage is placed at a position, for example, about 10 m to 20 m away from the storage case 29. The case 30 is provided, the cyclones 10, 11 and the filter device 17 are stored in the storage case 29, and the dehumidification device 19, the suction pump 21, the gas branching unit 24, and the gas analyzer 4a are provided in the other storage case 30. There is. Incidentally, 31 is a gas line connecting the filter device 17 and the dehumidifying device 19.

The operation of the sampling device thus constructed is the same as that of the first embodiment, and therefore its detailed description is omitted. The sampling device in which the sample gas pretreatment device is divided and arranged separately as in the second embodiment is suitable for, for example, a heavy oil-fired boiler, and can be easily added to an existing gas analyzer. .

FIG. 3 schematically shows a sampling apparatus according to the third embodiment of the present invention. In this embodiment,
Cyclones 10 and 11 are inserted in the flue 1. That is, the duct pipe 32 is inserted into the flue 1, the pre-stage cyclone 10 is arranged in the lower part, and the post-stage cyclone 11 is arranged in the upper part, and the probe 2 is provided at the tip of the duct pipe 32. ing.

Since the operation of the sampling device thus constructed is the same as that of the first and second embodiments, detailed description thereof will be omitted. And this third
In the case where the cyclones 10 and 11 are inserted and arranged in the flue 1 as in the embodiment, the configuration for gas sampling is simple, and the filter device 17 can be omitted. Further, since the cyclones 10 and 11 are heated by the heat in the flue 1, the heater 6 for preventing the drainage of the water in the sample gas S in the cyclones 10 and 11 can be configured with a small capacity. Note that this type of sampling device is suitable for, for example, a heavy oil-fired boiler.

The present invention is not limited to the above-mentioned embodiments, but can be implemented by being modified in various ways. For example, it is preferable that the cyclone provided in the sample gas supply path 3 is used properly according to the particle size distribution of dust or the like contained in the combustion exhaust gas G sampled from the flue 1, for example, particles of dust or the like. 2 or 3 when the diameter is widely distributed from small diameter to large diameter
It is better to connect the above cyclones in series. In that case,
It is preferable that a cyclone at a later stage can remove smaller dust and the like. Further, when the distribution of the dust or the like is not so wide, only a single cyclone may be provided.

The ejector devices 13 and 14 may be integrated with the cyclones 10 and 11,
The discharge pipe 16 downstream of the ejector devices 13 and 14 may be connected to a dust storage tank (not shown) for storing dust and the like.

In addition, in the first and second embodiments, when the amount of dust or the like and the water content in the sampled combustion exhaust gas G are not so large, either or both of the filter device 17 and the dehumidifying device 19 are used. It can be omitted.

Further, in each of the above embodiments, the gas analyzer 4 may be provided with a pump for sucking the sample gas S separately.

It goes without saying that the present invention can be widely applied not only to the combustion exhaust gas of the boiler but also to the sampling of a gas (high dust gas) containing a large amount of dust or the like in the exhaust gas.

[0043]

As described above, according to the present invention, a filter is used to separate and remove dust or the like in the sample gas, and the filter is blown back as in the prior art. Instead, the sampled combustion exhaust gas after passing through the cyclone and appropriately dusted is supplied to the ejector device installed in the cyclone as a utility gas, so there is no effect on sampling and gas analysis. Dust, etc. can be continuously separated and processed without affecting, that is, without interrupting or stopping sampling, etc. Therefore, the sample gas is also continuously supplied to the gas analyzer with high response. can do.

Since a part of the sample gas dedusted by the cyclone is supplied as a utility gas to the ejector device provided in the cyclone, a utility gas is separately prepared or supplied to the ejector device. The configuration such as piping for is greatly simplified.

[Brief description of drawings]

FIG. 1 is a diagram schematically showing a sampling device according to a first embodiment of the present invention.

FIG. 2 is a diagram schematically showing a sampling device according to a second embodiment of the present invention.

FIG. 3 is a diagram schematically showing a sampling device according to a third embodiment of the present invention.

FIG. 4 is a diagram for explaining a conventional technique.

[Explanation of symbols]

1 ... Flue, 2 ... Gas sampling section, 3 ... Sample gas supply path,
4 ... Gas analyzer, 10, 11 ... Cyclone, 13, 1
4 ... Ejector device, 15 ... Utility gas supply passage, 17 ... Filter device, 19 ... Dehumidifying device, 21 ... Pump, 24 ... Gas branch part, 26 ... Sample gas supply passage, G
… Combustion exhaust gas, S… sample gas, U… utility gas.

Front page continuation (72) Inventor Norio Kada 2 Higashimachi Co., Ltd., Higashimachi, Kichijoin-miya, Minami-ku, Kyoto, Kyoto Prefecture (72) Inventor Fujio Koga 2 Higashicho, Kichijoin-miya, Minami-ku, Kyoto, Kyoto Horiba Co., Ltd. In-house (72) Inventor Toshihiko Uno 2 Higashi-cho, Kichijoin-miya, Minami-ku, Kyoto-shi, Horiba Co., Ltd. (72) Inventor Shigeyuki Akiyama 2 Higashi-cho, Kichijo-in-miya, Minami-ku, Kyoto, Kyoto Horiba, Inc. Within

Claims (4)

[Claims] 1. A cyclone and a sample for separating dust and soot contained in a combustion exhaust gas as a sample gas sampled by the gas sampling unit in a sample gas supply path connecting the gas sampling unit and the gas analyzer. Sampling characterized in that a pump for sucking gas is provided in a state of being connected in series, and part of the sample gas that has passed through the cyclone is supplied as a utility gas to the ejector device provided in the cyclone via the pump. apparatus. 2. The sampling device according to claim 1, wherein a filter device and a dehumidifying device are connected in series between the cyclone and the pump. 3. A gas branch portion is provided at the latter stage of the pump, and a sample gas supply passage connected to one or more gas analyzers is connected to the gas branch portion, and a utility gas supply passage to the ejector device is connected. The sampling device according to claim 1 or 2. 4. The sampling device according to claim 1, wherein a cyclone is inserted and arranged in the flue.